The spontaneous firing pattern of forebrain neurons. I. The effects of dopamine and non-dopamine depleting lesions on caudate unit firing patterns

Unilateral lesions in and around the course of the nigrostriatal pathway (in the substantia nigra, in the supranigral region and more rostrally in the area of the medial forebrain bundle) in cats produced a marked slowing of single unit firing in the caudate nucleus contralateral to the lesion. In addition, the medial forebrain bundle lesion produced a tendency for an increase in unit firing rates in the caudate nucleus ipsilateral to the lesion. Lesions in the supranigral region in monkeys produced indications of a slowing in the firing rate of single units in the contralateral caudate and an increase in the firing rate of units in the caudate ipsilateral to the lesion. These alterations in spontaneous unit firing were independent of lesion-induced changes in concentrations of striatal dopamine or the activities of tyrosine hydroxylase and DOPA decarboxylase.     

The spontaneous firing patterns of forebrain neurons. IV. Effects of bilateral and unilateral frontal cortical ablations on firing of caudate, globus pallidus and thalamic neurons

To assess the effects of partial deafferentation of the neostriatum on spontaneous neuronal activity in the basal ganglia and related thalamic nuclei, ablations of frontal cortex were carried out in adult cats. Postoperative measures of interspike intervals of single neurons in the caudate nucleus, globus pallidus and ventral anterior-ventral lateral complex of the thalamus revealed a slowing of neuronal firing in these structures as compared with non-lesioned controls. The fact that deafferentation by cortical damage produces changes in neuronal firing in target neurons of the striatum (globus pallidus) and in thalamic neurons at least two synapses removed from the striatum is noteworthy. The possible extent to which these results might have been influenced by reduction of cortical inputs to or denervation of the thalamus is discussed.     

The spontaneous firing patterns of forebrain neurons. V. Time course of changes in caudate unit activity following dopamine-depleting lesions

The effects of unilateral medial forebrain bundle (‘MFB’) lesions on the spontaneous firing patterns of caudate neurons on both sides of the brain in cats were studied 3 days, 7 days and more than 2 weeks postlesion. Our results indicate that: (1) the spontaneous firing of neurons in the caudate nucleus ipsilateral to the lesion slows significantly by 3 days postlesion and returns to control values by 7 days postlesion, (2) the spontaneous activity of contralateral caudate neurons slows progressively with postlesion time and (3) these changes in neural activity are not correlated with changes in dopamine concentrations in the caudate nucleus.     

The spontaneous firing patterns of forebrain neurons. II. Effects of unilateral caudate nuclear ablation

Mean interspike intervals and the frequency of bursting were computed from records of spontaneous single unit activity of neurons in the caudate nucleus, the ventral anterior-ventral lateral complex of the thalamus and the precruciate cortex in intact unanesthetized cats and in cats with unilateral ablation of the caudate nucleus. In intact cats caudate nuclear units fired more slowly and produced a lower number of bursts than units in the cortex. Thalamic units showed an even greater frequency of unit firing and more bursting than cortical units. Unilateral caudate ablation was followed by a marked slowing of unit firing and a decrease in bursting in the opposite caudate nucleus (compared to values recorded in intact controls). Firing rate and bursting were relatively unaffected in the cortex and thalamus. These results are interpreted as indicating that removal of the influence of caudate output neurons on their target cells in the globus pallidus and substantia nigra mediate the marked decreases in firing of contralateral caudate neurons.     

Biochemical and behavioral effects of serotonin neurotoxins on the nigrostriatal dopamine system: Comparison of injection sites

Unilateral injections of the serotonin neurotoxin, 5,7-dihydroxytryptamine (DHT), at various points along the 5-HT pathway to the forebrain produce a turning syndrome associated with alterations of dopamine synthesis in the ipsilateral striatum. Unilateral injections of DHT into the SN produced an ipsilateral increase in striatal dopamine (DA) turnover and contralateral rotation in response to amphetamine or apomorphine. Injection of DHT into the MFB produced an ipsilateral decrease in striatal DA turnover and tyrosine hydroxylase (TOH) activity, and ipsilateral rotation in response to amphetamine or apomorphine. After the injection of DHT into the SN or MFB, there was a significant correlation between the rates of drug-induced rotation, the decrease in cortical 5-HT turnover, and the change in striatal DA turnover, suggesting that the unilateral change in DA turnover (and, presumably, the increased stimulation of DA receptors) is causally linked to turning. Injection of DHT into the zones of the striatum and GP richest in 5-HT terminals produced the same responses as the MFB-lesioned rats: ipsilateral rotation and a decrease in striatal TOH activity. Injection of DHT into the area of the striatum richest in DA terminals failed to produce rotation or a significant change in TOH activity. We suggest that 5-HT neurons from the raphe nuclei exert a tonic inhibition on the nigrostriatal pathway at the level of the SN through direct synapses on DA neurons, whereas their neostriatal terminals have an indirect effect on DA terminals, perhaps via interaction with cholinergic and GABA-ergic neurons.     

The effects of acetylcholine and dopamine on the caudate nucleus depleted of biogenic amines.

Because it has been proposed that the reduction of the striatal biogenic amines in Parkinson's disease leads to an imbalance between the actions of acetylcholine and dopamine, we have studied the effects of these substances, liberated from multibarrelled micropipettes, on the firing of single neurons in the feline caudate nucleus depleted of biogenic amines by long-standing nigrostriatal lesions. Compared with neurons in intact cats, those in cats with lesions were more easily excited by acetylcholine and less easily supressed by dopamine. These results suggest that the depletion of the striatal amines decreases the neuronal susceptibility to dopamine and increases that to acetylocholine, possibly by changing the sensitivity or the number of the neuronal receptors of these agents.     

Selective blockade by scopolamine of synaptic responses in cat's caudate nucleus and its modification by lesions of the substantia nigra.

Because it is commonly believed that acetylcholine is a synaptic transmitter in the caudate nucleus and that the reduction of striatal biogenic amines in Parkinson's disease leads to acetylcholine supersensitivity in the caudate nucleus, we investigated the effects of the muscarinic blocking agent scopolamine on synaptic responses of neurons in the intact feline caudate nucleus and in the caudate nucleus depleted of dopamine by long-standing nigrostriatal lesions. In the intact caudate nucleus, micro-iontophoretic application of scopolamine selectively blocked the neuronal responses to stimulation of the caudate nucleus near the recording site without affecting the responses to stimulation of the sensorimotor cortex or the substantia nigra in the same fashion. This suggests that acetylcholine is a synaptic transmitter of caudate interneurons. Responses to thalamic stimuli were also blocked by scopolamine, suggesting that acetylcholine may be a transmitter of thalamic afferents although the course of these afferents is unclear. In the dopamine-depleted caudate nucleus scopolamine was more effective than in the intact caudate nucleus blocking the neuronal responses to stimulation of the caudate nucleus. This greater blocking effect by scopolamine suggests an increased effect of endogenous acetylcholine in this response and supports previous observations of an increased excitatory effect of iontophoretic acetylcholine in the dopamine-depleted caudate nucleus. These results suggest that the acetylcholine supersensitivity which follows nigrostriatal degeneration may be due to increased effectiveness of synaptic transmission by cholinergic interneurons in the caudate nucleus.     

Neglect of contralateral visual stimuli in monkeys with unilateral striatal dopamine depletion.

Unilateral lesions of the nigrostriatal dopaminergic system were induced by injecting 6-hydroxydopamine into the substantia nigra of three monkeys trained to initiate arm movements in response to stimuli randomly presented at various locations in their immediate visual space. This procedure resulted in partial reduction of dopamine content, as compared to intact side, in both the putamen and caudate nucleus, with the exception of the putamen in one monkey. A concomitant reduction in the level of dihydroxyphenylacetic acid was observed, but less systematically than the dopamine decrease in the same striatal regions. All monkeys displayed a predominant contralateral arm hypokinesia consisting of a slowness in initiating movements, little or not affected by the hemispace of presentation of the trigger stimulus. Conversely, when the monkeys responded with the arm ipsilateral to the lesion, the movement was initiated more slowly when the trigger stimulus was presented to the hemispace contralateral to the striatal dopaminergic depletion as compared to the ipsilateral hemispace. The results suggest that the visual neglect is more conspicuous when monkeys performed with the arm ipsilateral to the damaged nigrostriatal system. This neglect may be described as a disorder in the ease with which stimuli presented to the side contralateral to the impaired dopaminergic transmission are able to elicit behavioral responses, possibly as the result of a lack of selective attention or defective movement initiation.     

Excitation and inhibition processes in the neurons of the thalamic motor nuclei of normal cats and following an N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine-induced lesion of the nigrostriatal dopaminergic system

Peculiarities of excitation and inhibition evoked in motor thalamic nuclei (VA-VL) neurons by electrical stimulation of red nucleus were studied on intact cats and after injection of N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP; 5 mg/kg i.m., p.d. during five days). Two days after the last injection as much as 48% of nigral neurons were destroyed and the content of dopamine in the caudate nucleus fell to 30% as compared to intact animals. Before acute experiments all cats were anaesthetized with ketalar and immobilized with myorelaxine. It was found that MPTP injections caused a decrease of the inhibition duration and effectiveness in relay and nonrelay VA-VL neurons. The inhibition deficiency was accompanied by shortening of latencies of orthodromic responses evoked by red nucleus stimulation and facilitation of antidromic spikes invasion into somata of relay neurons after motor cortex stimulation. It was suggested that the reduction of GABAergic nigro-thalamic influences modulated by dopamine underlay the developing deficiency of inhibition.     

A role of the striatum in premotor cortical seizure development

Striatal function in partial seizure development induced by low frequency cortical stimulation of the ipsilateral premotor cortex was investigated by either electrolytic lesion placement or microinjection of putative neurotransmitter-related drugs into the ipsilateral striatum. Unilateral striatal lesioning and intrastriatal injection of muscimol, a GABA-agonist, and glutamic acid diethylester, a presumed antagonist for glutamatergic neurotransmission, were effective in suppressing seizure development, whereas intrastriatal injection of a subconvulsive dose of carbamylcholine chloride (carbachol), a cholinergic agonist, decreased the seizure threshold. In contrast to the ipsilaterally dominant metabolic activation in the intact animal, an inverse asymmetry due to a considerable reduction of deoxyglucose uptake in the ipsilateral thalamus, entopeduncular nucleus, substantia nigra, striatum and surrounding cortex of the focus was found in those brains with striatal lesion. Altogether, the findings suggest that experimental reduction of the inhibitory striatal outputs to both the entopeduncular nucleus and the substantia nigra enhances tonic activities of the projection GABAergic neurons in those nuclei, thereby inhibiting seizure development.     

Intralaminar thalamic nuclei lesions: widespread impact on dopamine denervation-mediated cellular defects in the rat basal ganglia

Intralaminar thalamic nuclei represent a major site of non-dopaminergic degeneration in Parkinson disease, but the impact of this degeneration on the pathophysiological functioning of basal ganglia remains unknown. To address this issue, we compared the effects of 6-hydroxydopamine-induced lesions of nigral dopamine neurons alone or combined with ibotenate-induced lesions of intralaminar thalamic neurons on markers of neuronal metabolic activity in the rat basal ganglia using in situ hybridization histochemistry. Thalamic lesions prevented most of the dopamine denervation-induced changes (i.e. the increases in mRNA levels of enkephalin and GAD67 in the striatum, of GAD67 in the globus pallidus and entopeduncular nucleus, and of cytochrome oxidase subunit-I in the subthalamic nucleus), but did not affect the downregulation of striatal substance P and upregulation of GAD67 in the substantia nigra pars reticulata. We also provide immunohistochemical evidence that thalamic lesions markedly decreased striatal expression of the vesicular glutamate transporter vGluT2, confirming the association of this transporter with the thalamic projections to the basal ganglia. Altogether, these data reveal a major antagonistic influence of thalamic and dopaminergic afferents onto the basal ganglia and suggest that degeneration of thalamic neurons in Parkinson disease may represent an important factor counteracting expression of the defects associated with the dopamine denervation.     

Effects of dorsal and ventral striatal lesions on delayed matching trained with retractable levers

Recent evidence has suggested that thalamic amnesia results from damage to the intralaminar nuclei, an important source of input to striatum. To test the hypothesis that intralaminar damage disrupts functions mediated by striatum, we studied the effects of striatal lesions on a delayed matching task known to be affected by intralaminar lesions. Rats were trained to perform the task and given one of five treatments: sham surgery or a lesion of medial or lateral caudate/putamen, nucleus accumbens, or ventral striatum. Rats with ventral striatal lesions were impaired compared to all other groups. Rats with medial caudate/putamen or nucleus accumbens lesions were impaired compared to controls. The effects of ventral striatal lesions were sufficient to account for impairments in the accuracy and latency of delayed matching responses observed in previous studies of intralaminar and medial frontal cortical lesions. The ventral striatal lesions involved portions of ventral pallidum and thus it seems likely that they affected functions mediated by the nucleus accumbens as well as striatal areas of the tubercle. Serial reversal learning trained in the same apparatus with the same reinforcer was unaffected by all of the lesions. These results are discussed in terms of the roles of midline thalamic nuclei and of thalamo-cortico-striatal circuits in delayed conditional discrimination tasks.     

Thalamic projections of nucleus reticularis thalami of cat: a study using retrograde transport of horseradish peroxidase and fluorescent tracers

The retrograde transport of horseradish peroxidase (HRP) and fluorescent tracers after injections in various thalamic nuclei was used to investigate the relative density of retrogradely labeled cells in different districts of reticularis thalami (RE) nuclear complex of cat. The RE nucleus was left virtually free of labeling only after injections localized into the anterior nuclear group; in those experiments, heavy retrograde labeling was obtained in mammillary nuclei. The major targets of RE cells proved to be centralis lateralis-paracentralis (CL-PC) and centrum medianum-parafascicularis (CM-PF) intralaminar nuclei. The projections to various intralaminar nuclei mainly arise in the rostral pole and rostrolateral part of RE nucleus and are reciprocal to intralaminar-RE pathways disclosed by Jones ('75). The RE territories labeled following injections in relay and associational nuclei are more restricted and are located contiguously and slightly anteriorly to a given nucleus. There was a very small proportion of doubly labeled RE cells after injections with fluorescent tracers in different nuclei. This was not due to a technical failure since many double-labeled neurons were found in the same material in medial globus pallidum after thalamic and midbrain injections (see companion paper by Parent and Steriade, '84). We conclude that most individual RE axons arborize in only one thalamic nucleus or nuclear group. An additional finding was the existence of intralaminar-to-relay (CL-PC to VA-VL) projections.     

Subthalamic nucleus lesion improves cell survival and functional recovery following dopaminergic cell transplantation in parkinsonian rats

Subthalamic nucleus (STN) modulation is currently the gold standard in the treatment of Parkinson's disease (PD) cases refractory to medication. Cell transplantation is a tissue‐restorative approach and is a promising strategy in the treatment of PD. One of the obstacles to overcome in cell therapy is the poor dopaminergic cell survival. Our experiment investigates the impact of a partial subthalamotomy prior to ventral mesencephalic (VM) embryonic cell transplantation on dopaminergic cell survival and functional outcome. Unilateral dopamine depletion was carried out in rats, via medial forebrain bundle (MFB) injection of 6‐hydroxydopamine, and half of the animals went on to receive unilateral excitotoxic lesions of the STN/Zone Incerta (ZI) causing partial lesion of these structures on the same side as the MFB lesion. All MFB‐lesioned animals, with or without the STN/ZI lesion, received striatal ipsilateral embryonic VM cell grafts. The data suggest that the STN/ZI lesion could boost the dopamine cell survival in the grafts by 2.6‐fold compared with the control grafted‐only group. Moreover, performance on the drug‐induced rotation and the spontaneous behavior tests were ameliorated on the STN/ZI‐lesioned group to a significantly greater extent than the grafted‐only group. These data suggest that the STN/ZI partial lesion optimized the striatal environment, promoting an improvement in cell survival. Further studies are needed to see whether the synergy between STN modulation via deep brain stimulation and cell therapy might have clinical applications in the management of PD.     

Cholecystokinin: Corelease with dopamine from nigrostriatal neurons in the cat

Halothane-anaesthetized cats were implanted with push-pull cannulae to demonstrate the in vivo release of cholecystokinin-like immunoreactivity (CCK-LI) in the substantia nigra and the ipsilateral caudate nucleus. The spontaneous and the calcium-dependent potassium-evoked release of CCK-LI were observed in both structures. In addition, the local application of tetrodotoxin (10-6 M) reduced the spontaneous release of the peptide. 6-OHDA lesions made in the substantia nigra pars compacta led to a complete destruction of nigrostriatal dopaminergic neurons. CCK-LI levels were not affected in the caudate nucleus but were reduced substantially in the substantia nigra. The activation of dopaminergic cells induced by the nigral application of alpha-methyl-para-tyrosine (10-4 M) stimulated the release of CCK-LI and dopamine in the ipsilateral caudate nucleus, whilst opposite effects were seen in the substantia nigra. Similar results were obtained when dopaminergic transmission was blocked in the caudate nucleus suggesting that the evoked release of CCK-LI by the alpha-methyl-para-tyrosine treatment originates from dopaminergic nerve terminals and not from other CCK-LI containing fibres in response to released dopamine. Dopamine (10-7 M) as well as the D1 agonist SKF 38393 (10-5 M) stimulated CCK-LI release when applied into the caudate nucleus while the D2 agonist, LY 171555 (10-6 M) slightly reduced peptide release. The local application of cholecystokinin-8 sulfate (CCK-8S) (10-8 M, for 30 min) into the substantia nigra pars compacta increased the firing rate of dopaminergic cells and stimulated the release of newly synthesized 3H-dopamine from dendrites and nerve terminals. These results suggest, but do not definitively prove, that, in the cat, CCK-LI and dopamine are coreleased from nigrostriatal mixed dopaminergic/CCK-LI neurons and that CCK-LI released from dendrites is, like dopamine, involved in the regulation of the activity of these cells.     

Vestibular input to the caudate nucleus

Unilateral stimulation of peripheral vestibular nerve branches in encephale isolé cats evoked potentials of 3- to 7-msec latency in the banks of the contralateral anterior suprasylvian sulcus and 4- to 15-msec latency in the head of the caudate nucleus bilaterally. The responses were distributed in the dorsomedial region of the ipsilateral caudate and dorsolateral region of the contralateral caudate. Stimulation of peripheral cochlear nerve branches also evoked responses in areas of caudate partially overlapping those responsive to vestibular stimulation. Stimulation of the vestibular projection area of cortex evoked a response in caudate but did not alter the response to vestibular nerve stimulation. Ablation of the vestibular projection area of cortex did not alter the vestibular responses in caudate. However, caudate and cortical responses to vestibular nerve stimulation were severely decreased by lesions of the magnocellular portion of medial geniculate body. We conclude that there are vestibular projections to the caudate nuclei which require passage through the medial geniculate body and probably other thalamic nuclei, but not through the vestibular projection area of cortex.     

The effect of acetylcholine and dopamine on the caudate spindle in cats

Electrocortical activity was reacorded in cats whose caudate nuclei were perfused and electrically stimulated using a push-pull cannula. Electric stimulation invariably induced spindles (10-14 Hz) in the ipsilateral frontal cortex. Perfusions of acetylcholine together with physostigmine reduced the number of spontaneous spindles, the response to electric stimulation and induced behavioural arousal. This effect was atropine-sensitive. Perfusions of dopamine with or without tranylcypromine had no significant effect on the number of spontaneous spindles or the response to electric stimulation. Injections of both acetylcholine and dopamine into the cuadate nucleus invariably induced spontaneous spindles and slow waves. The significance of acetylcholine and dopamine in the caudate nucleus intiating caudate spindles and their significance in controlling arousal is discussed.     

Nucleus basalis involvement in conditioned neuronal responses in the rat frontal cortex

Rat frontal cortex neurons exhibit alterations in firing in response to a 2 sec tone cue followed by rewarding medial forebrain bundle (MFB) stimulation. Nucleus basalis neurons supply up to 75% of the cortical cholinergic innervation. The nucleus basalis and ACh have been implicated as playing a role in cognitive function. Three experiments were designed to test the hypothesis that the nucleus basalis cholinergic system is involved in the generation of conditioned neuronal responses in the rat frontal cortex. Local microinjection of the cholinergic antagonist, atropine, into the frontal cortex suppressed the conditioned responses of 22 of 25 cortical single units. Unilateral kainic acid lesioning of the nucleus basalis resulted in a significant decrease in the proportion of units exhibiting conditioned responses in the cortex ipsilateral to the lesion (25%) compared to the proportion of responding units from the cortex of untreated animals (70%). When the firing rates of units encountered in the region of the nucleus basalis were monitored during presentation of the cue-MFB paradigm, 28 of 38 unit recordings exhibited significant increases or decreases in firing rate. Therefore, the results of the experiments indicate that the nucleus basalis cholinergic neurons are involved in the generation of conditioned neuronal responses in the rat frontal cortex.     

Changes in [3H]muscimol binding in substantia nigra, entopeduncular nucleus, globus pallidus, and thalamus after striatal lesions as demonstrated by quantitative receptor autoradiography

A quantitative autoradiographic technique for measuring the binding of [3H]muscimol to central nervous system GABA receptors is described using tritium-sensitive film. [3H]Muscimol binding was studied in primary and secondary striatal projection areas of rat brain following kainic acid lesions of the striatum. Seven days after the lesion, binding affinities in the striatum and its projection areas were not altered significantly. There was a loss of [3H]muscimol receptors in the striatum. Receptors increased in numbers in the ipsilateral globus pallidus (19%), entopeduncular nucleus (22%), and substantia nigra pars reticulata (38%). [3H]Muscimol binding was decreased in the ipsilateral anteroventrolateral and ventromedial (8%) thalamic nuclei. [3H]Muscimol binding in other brain areas (layer IV of the cerebral cortex, central gray, superior colliculus, and stratum moleculare of hippocampus) was not affected. The findings suggest that a loss of striatal innervation resulted in increased numbers of GABA receptors in striatal projection sites. It is further suggested that loss of inhibitory striatal inputs to neurons in the entopeduncular nucleus and substantia nigra pars reticulata may activate GABAergic projections to thalamus and thus result in decreased numbers of thalamic GABA receptors.     

Thalamostriatal neurons with collateral projection onto the rostral reticular thalamic nucleus: anatomical study in the rat by retrograde axonal transport of iron-dextran and horseradish peroxidase

Injection of horseradish peroxidase (HRP) into the head of the reticular thalamic nucleus (RT) of rats having undergone large cortical and striatal lesions, led to the labeling of thalamic neurons in medial thalamic nuclei. After injection of iron-dextran into the corpus striatum and HRP into the rostral RT of intact rats, double-labeled neurons were observed in the medial thalamus, mainly in the central lateral nucleus.